KR910008485B1 - Solar ray-collecting device - Google Patents

Abstract

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Description

Solar collector

1 is a perspective view for explaining an embodiment of the solar collector previously proposed by the applicant.

2 to 4 are diagrams for explaining embodiments of a conventional solar collection device.

5 is a configuration diagram for explaining an embodiment of a photovoltaic collection device according to the present invention.

* Explanation of symbols for main parts of the drawings

1: protective capsule 2: lens

2a: light exit end of the lens 3: lens holding mechanism

4: direction sensor 5: optical conductor cable (optical fiber)

6: fiber holder 7: arm

8, 11: pulse motor 9: horizontal axis of rotation

10: pedestal 12: vertical axis of rotation

13: optical conductor cable 20: optical coupling

20a: light receiving end 20b: light emitting end

20c: circumferential surface θ ₁ to θ ₄ : angle

C: curved surface

The present invention relates to a photovoltaic collection device that effectively introduces sunlight connected by a Fresnel lens into an optical conductor cable.

The applicant has previously proposed a solar collector made of a plurality of lenses. It is introduced into the optical conductor cable focused by the lenses.

The solar light introduced in this way is transferred to any desired place via the optical conductor cable.

In the solar collector as described above, when the aperture angle of the lens is large, the image of the sun connected by the lens is small.

Small diameter conductor cables can thus be used, which is advantageous in size.

However, the rising angle at the periphery of the lens is large, and the reflection of light in this portion is increased, resulting in poor connection efficiency and incidence of incidence on the optical conductor cable, which increases reflection at the light receiving end of the optical conductor cable. Light introduction efficiency to a cable worsens.

In addition, the light introduced into the lens is reflected at the light exit end side of the lens and returned to the lens, which then propagates into the lens, so that the incident sunlight cannot be efficiently maintained in the light conductor.

On the other hand, when the aperture angle of the lens is small, the rising angle in the lens periphery is small, the reflection at this portion is small, and the incident angle with respect to the optical conductor cable is small, and the reflection at the optical cable receiving end is also small. However, the collecting efficiency is good, but on the other hand, there is a drawback that the cost of the optical conductor cable is high because the image of the sun forming the image is enlarged and the diameter of the optical conductor cable must be increased.

The present invention has been made to solve the above-mentioned drawbacks of the prior art, and in particular, it is possible to use a large numerical aperture for an optical conductor cable and to eliminate the reflection at the light receiving end of the optical conductor cable. It aims at maintaining the high efficiency of introduction of light into a cable.

In addition, an object of the present invention is to reduce the diameter of the optical conductor cable to reduce the cost of the optical conductor cable.

FIG. 1 is a detailed perspective view illustrating one example of a solar collector to which the present invention is applied. In FIG. 1, reference numeral 1 denotes a protective capsule which is a transparent body, and (2) a Fresnel lens, ( 3) a lens holding mechanism, (4) a sunlight direction sensor for detecting the direction of sunlight, (5) an optical fiber (or photoconductor cable) having a light receiving end disposed at a focal point of the Fresnel lens (2), ( 6) is a fiber holder, (7) is an arm, (8) is a pulse motor, (9) is a horizontal axis of rotation rotated by an impulse motor (8), and (10) is the protective capsule (1). A pedestal for mounting, 11 is another pulse motor, and 12 is a vertical axis of rotation rotated by this pulse motor 11.

As the applicant has already proposed before, the above-mentioned solar light collecting device detects the direction of the sun by (4) in the sunlight direction, and by the detection signal, the solar direction sensor 4 The driving motors 8 and 11 of the horizontal rotating shaft 9 and the vertical rotating shaft 12 are directed to face each other so that the sunlight collected by each lens 2 is the focal position of each lens. Is introduced into the optical fiber 5 in which the light receiving end is disposed. The optical fiber or conductor cable 5 disposed for each lens is combined with each other to form a cable 13 and is led out of the solar collector and led to any desired place where they are used.

2 and 3 are each a configuration diagram for explaining the embodiments of the conventional solar collection device. 2 and 3, reference numeral 2 denotes a lens for connecting sunlight, and 5 denotes an optical conductor cable into which solar light connected by the lens is introduced, and FIG. Is an embodiment when the numerical aperture (angle) is large, and FIG. 3 shows an embodiment when the numerical aperture (angle) of the lens 2 is small.

Thus, as shown in FIG. 2, when the aperture angle of the lens 2 is large, the image of the sun formed by the lens 2 becomes small, so that a small diameter optical conductor cable can be used. In this case, the rising angle θ ₁ of the periphery of the lens 2 is increased, on the other hand, the reflection of light in this portion is increased, the focusing efficiency is worsened, and the incident angle θ ₂ to the optical conductor cable 5 is increased. The reflection at the light receiving end of the optical conductor cable 5 becomes large, and the introduction efficiency into the optical conductor cable 5 becomes worse.

In addition, the light introduced into the lens 2 is reflected at the light exit end 2a side of the lens to be returned to the lens 2, and then propagated into the lens 2, whereby the incident sunlight is efficiently emitted. It cannot be guided by the conductor cable.

On the other hand, if the third, as also shown in the small opening angle of the lens 2, the rising angle θ ₃ of the lens periphery small, the reflection in this portion is small, and the incident angle θ ₄ of the optical conductor cable (5) Since the reflection becomes smaller at the light receiving end of the optical conductor cable 5, the collection efficiency is good, while the image of the sun formed by the lens 2 becomes larger, so that the diameter of the optical conductor cable has to be increased. There is a drawback that the cost of an optical conductor cable is very high.

FIG. 4 is a diagram schematically showing the main part when a Fresnel lens is used instead of a lens having a large opening angle as shown in FIG.

As is well known, the Fresnel lens effectively utilizes the curved surface C of the normal lens as shown in Fig. 2, and the thickness of the Fresnel lens is reduced and the weight of the whole is made light. Use of such a Fresnel lens in place of the lens shown in FIG. Makes it possible to miniaturize and reduce the weight of the device, and in particular, in the case of moving the lens in accordance with the movement of the sun, the moving part is lightened and moves according to the moving part. This has the advantage of being faster.

The second case in which the opening angle is also large lenses, as shown in a Fresnel lens in principle, the opening angle is large lens for _{A 1, A 2, A 3} ... And the like, and the cut portions of these lenses are flat on the plane, A ₁ , A ₂ , A ₃ . Formed in a row in order, and the lens surfaces S ₁ , S ₂ , S ₃ . Is used as the lens surface of the Fresnel lens.

In this case, the lenses may be replaced with A ₁ , A ₂ , A ₃ . Surface B ₁ , B ₂ , B ₃ . Must be inclined as shown in FIG. 4, and in such a configuration, W ₁ , W ₂ . The amount of light equivalent to cannot be used, which was inefficient.

The present invention has been made to solve the above-mentioned drawbacks of the prior art, and in particular, it is possible to use a large numerical aperture for an optical conductor cable, and the optical conductor cable eliminates reflection at the light receiving end, An object of the present invention is to maintain a high efficiency of introducing light into the optical conductor cable.

Moreover, an object of this invention is to reduce the cost of an optical conductor cable by making it possible to make the diameter of the said optical conductor cable small.

5 is a configuration diagram for explaining an embodiment of the solar collection device according to the present invention.

In Fig. 5, reference numeral 2 denotes a Fresnel lens for solar connection, 5 denotes an optical conductor cable, and 20 denotes a light-receiving end 20a side with a large area and a light exit end 20b side. As the optical coupling consisting of a truncated conical photoconductor formed with this small area, in the present invention, a condensing lens is used as the condensing lens, in other words, a Fresnel lens having a small numerical aperture, that is, a small rising angle of the periphery.

However, the Fresnel lens 2 having a small numerical aperture has a small rate of rise at the periphery, less reflection at the periphery, and can be obliquely cut as described in FIG. Solar light can be connected efficiently.

However, since the image of the sun focused by the Fresnel lens 2 having such a small numerical aperture is large, when the light connected to the Fresnel lens 2 is to be introduced into the optical conductor cable 5 as it is, the optical conductor cable ( 5) As the diameter must be used, the cost is very high.

On the other hand, if the diameter of the optical conductor cable 5 is to be reduced, the opening angle of the lens 2 should be made small by increasing the opening angle of the lens 2, but if the opening angle of the lens 2 is increased, as described above, There exists a problem that the incident angle of the light in the incident end surface of the optical conductor cable 5 becomes large, and the reflection loss in this incident end surface becomes large.

Thus, in the present invention, the Fresnel lens 2 having a relatively small numerical aperture as described above using the optical coupling 20 having a large area on the light receiving end 20a side and a small area on the light emitting end 20b side. The solar image of the fertilizer-large phase connected by is received in the wide area 20a of this optical coupling 20, and is introduce | transduced into the two-light coupling 20. As shown in FIG.

In this way, the light introduced into the optical coupling 20 travels toward the light exit end 20b while repeating the reflection at the peripheral surface 20c of the optical coupling 20, and the aperture angle is repeated during the reflection. The opening angle at the light exiting end 20b becomes substantially larger than the numerical aperture of the optical conductor cable 5.

Therefore, as long as the light emitted from the optical coupling 20 can be introduced into the optical conductor cable 5, it is most efficient to propagate in the optical conductor cable 5, and thus the light is effectively transmitted. To be.

However, as described above, when the numerical aperture of the optical conductor cable 5 is large, even if this large numerical aperture is intended to introduce light having the same incident angle (opening angle) into the optical conductor cable 5, this optical The reflection loss in the light receiving end surface of the conductor cable 5 is large, and light cannot be efficiently introduced into the optical conductor cable 2.

Therefore, in the present invention, the light exiting end 20b of the optical coupler 20 is integrally bonded to the light receiving end surface of the optical conductor cable 5 by an optical pull or the like, and thus the light receiving end of the optical conductor cable 5 There can be almost no reflection loss in the cross section.

As apparent from the above description, according to the present invention, the use of a Fresnel lens having a small numerical aperture reduces the reflection loss at the lens periphery as compared with the case of using a Fresnel lens having a large numerical aperture.

At the same time, the area of the oblique cut necessary for forming the Fresnel lens can be made small so that the light can be efficiently connected.

In addition, the use of a light coupling having a large light receiving area enables the use of a Fresnel lens having a small numerical aperture, thereby reducing the reflection loss on the light receiving surface of the light coupling.

Furthermore, by allowing sunlight to pass through this optical coupling, the aperture angle of sunlight can be enlarged, and this aperture angle can be enlarged to the maximum aperture angle which a photoconductor cable can receive.

This makes it possible to use optical conductor cables having a large numerical aperture, thus enabling the use of optical conductor cables with small diameters.

As a result, the optical conductor cable can save cost.

In addition, by using an optical pool or the like, the light exiting end of the optical coupling is integrally bonded with the light receiving end of the optical conductor cable, whereby the reflection loss at the light receiving end of the optical conductor cable can be almost completely improved.

Claims (1)

The sunlight 2 which consists of the lens 2 for connecting sunlight, the optical coupling 20 which consists of the conical optical conductor cut off, and the optical conductor cable 5, and is connected to the said lens 2 Is introduced into the end area 20a of the wide area of the conical optical coupling 20 cut off, and the end area 20b of the narrow area of the optical coupling 20 of this conical phenomenon cut off. A solar collector which introduces emitted light into the optical conductor cable (5), wherein the optical conductor cable (5) has an incident angle of sunlight on the light incident surface of the optical conductor cable (5). When the numerical aperture of the optical conductor cable 5 is the same or more, it has a large reflection loss, and the said lens 2 is comprised by the Fresnel lens of numerical aperture smaller than the numerical aperture of the said optical conductor cable 5, The optical coupling 20 has a numerical aperture equal to the numerical aperture of the optical conductor cable 5. Outgoing light end (20b) of the outgoing light has an edge (20b), the optical coupling 20 is the solar collection device, characterized in that it is bonded to the light-receiving optical full end of the optical conductor cable (5).

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